A face side material temporary storage mechanism and a recycling device

By using a combination design of a temporary storage tray and a translation stage in the edge material recycling device, along with a guiding mechanism and an anti-stick coating, the problem of edge material sticking when the conveyor belt stops suddenly is solved, achieving uniform temporary storage and efficient recycling of edge material.

CN224482799UActive Publication Date: 2026-07-14WUHAN QIANJI FOOD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
WUHAN QIANJI FOOD CO LTD
Filing Date
2025-07-04
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Edge material tends to accumulate or scatter when the conveyor belt stops suddenly, leading to adhesion and contamination, which affects subsequent processing and recycling efficiency.

Method used

The system employs a combination of a temporary storage tray and a translation table, which prevents the edge material from sticking by allowing free movement in the X and Y axes. Combined with a guiding mechanism and an anti-stick coating design, it ensures the uniform spreading and conveying of the edge material.

Benefits of technology

It effectively prevents the edges of the dough from sticking together during temporary storage and transportation, ensuring smooth recycling and convenient secondary processing, and reducing raw material waste and equipment pollution.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the technical field of noodle production, in particular to a noodle edge material temporary storage mechanism and a recycling device, which comprises a temporary storage disc and a translation table, the temporary storage disc is located on the translation table, the temporary storage disc is detachably connected with the translation table, and the temporary storage disc is connected with the translation table and used for free movement of the temporary storage disc in X and Y axis directions on the plane. The application has the advantages that the temporary storage disc is placed on the translation table, the translation table can freely move the temporary storage disc in X and Y axis directions on the plane, the noodle edge material can be evenly laid on the temporary storage disc, the noodle edge material is effectively prevented from being adhered together, and the effect of subsequent recycling and secondary processing of the noodle edge material is facilitated.
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Description

TECHNICAL FIELD

[0001] The present application relates to the technical field of noodle production, in particular to a noodle edge temporary storage mechanism and a recycling device. BACKGROUND

[0002] With the development of science and technology, the noodles frequently consumed in daily life of people gradually move towards industrial production. In the production process of noodles, the edge part is often hard in texture and poor in taste due to the reason of machine pressing mold, and the edge part often forms irregular shape, which is difficult to handle in subsequent processing.

[0003] To solve the above problems, the factory machine usually cuts the edge of the noodles, and then separates the edge part through a baffle, which can ensure that the shape and size of the noodles are more standardized, meet the market demand and the requirements of consumers for product appearance, and also can retain the part with soft and good texture. However, the waste or dough crumbs cut off are guided to the edge of the equipment by the baffle, and then scattered around the equipment, causing waste of raw materials.

[0004] Generally, a simple recycling device is placed beside the baffle to recycle the noodle edge, or a conveyor belt is used to convey the generated noodle edge to a secondary processing place. However, when the conveyor belt suddenly stops due to failure, the noodle edge will accumulate on the conveyor belt or fall to the ground to cause pollution. Since the surface of the noodles is moist during production, the noodle edge accumulated on the conveyor belt will stick together, which is not convenient for subsequent secondary processing.

[0005] Therefore, in the production process, if the conveyor belt suddenly stops, how to temporarily store the noodle edge on the conveying assembly becomes a problem to be solved. SUMMARY

[0006] The purpose of the present application is to provide a noodle edge temporary storage mechanism. The technical scheme adopted is as follows:

[0007] The temporary storage mechanism comprises a temporary storage disc and a translation table.

[0008] The temporary storage disc is located on the translation table, and the temporary storage disc is detachably connected with the translation table. The connection between the temporary storage disc and the translation table is used for free movement of the temporary storage disc in X and Y axis directions on the plane.

[0009] By adopting the above technical scheme, when the noodle edge falls from the equipment, the temporary storage disc is placed on the translation table, and the translation table can freely move the temporary storage disc in X and Y axis directions on the plane, so that the noodle edge can be evenly laid in the temporary storage disc, effectively preventing the noodle edge from sticking together, and facilitating subsequent recycling and secondary processing of the noodle edge.

[0010] Optionally, the translation table is provided with a clamping jaw, and the clamping jaw is used for fixing the temporary storage disc.

[0011] By adopting the above technical solution, the gripper can clamp and fix the scratch disk, and prevent the scratch disk from shifting when the translation stage moves. At the same time, the detachable design makes it convenient and quick to replace the scratch disk.

[0012] A dough scrap recycling device includes a dough scrap temporary storage mechanism, a main body, and a guiding mechanism. The main body is equipped with a cutter, which is rotatably connected to the main body. The edge of the main body is provided with a discharge port, which corresponds to the cutter. The guiding mechanism is located at the discharge port, and the dough scrap temporary storage mechanism is located on the side of the discharge port below the main body.

[0013] By adopting the above technical solution, the dough scrap temporary storage mechanism and the dough scrap recycling device work together. The cutter completes the cutting of the dough, the guide mechanism discharges the cut dough scraps from the outlet, the dough scrap temporary storage mechanism can prevent the dough scraps from sticking together, and finally completes the recycling of the dough scraps.

[0014] Optionally, the guiding mechanism includes a guide wheel, a guide plate, an adjusting mechanism, and a conveying assembly; the guide wheel is located at the discharge port and is rotatably connected to the main body; one end of the guide plate is fixedly connected to the adjusting mechanism, and the other end is located at the discharge port; the adjusting mechanism is fixedly connected to the main body; and the conveying assembly is located below the main body.

[0015] By adopting the above technical solution, the cut edge material will hit the guide plate under the action of the main body conveyor belt, and move along the guide plate to the guide wheel. The guide wheel rotates and drives the edge material to be discharged from the outlet. The adjustment mechanism can adjust the deflection and position of the guide plate at any time to adapt to fabrics of different widths.

[0016] Optionally, the surface of the guide wheel has a spiral groove structure.

[0017] By adopting the above technical solution, the spiral groove structure guides the edge material to move along a predetermined trajectory through the centrifugal force generated by rotation. Compared with the flat wheel surface, the spiral groove can increase the sliding speed of the edge material, effectively preventing the material from accumulating on the wheel surface. At the same time, the groove edges form intermittent contact, reducing the adhesion between the edge material and the wheel surface.

[0018] Optionally, the conveying assembly includes a second conveyor belt located below the main body, with the starting end of the second conveyor belt located between the discharge port and the edge material temporary storage mechanism.

[0019] By adopting the above technical solution, the edge material is discharged from the outlet to the second conveyor belt and transported by the second conveyor belt. A temporary storage tray is provided at the starting end of the second conveyor belt below the main body, corresponding to the outlet. When the second conveyor belt malfunctions and needs to be stopped for maintenance, the edge material can be temporarily placed in the temporary storage tray, without having to stop the entire machine for maintenance.

[0020] Optionally, the surface of the second conveyor belt is provided with an anti-stick coating.

[0021] By adopting the above technical solution, the edge material has a certain degree of stickiness. When it falls onto the second conveyor belt, it will stick to the second conveyor belt and be difficult to fall off. The anti-stick coating can prevent the edge material from sticking to the second conveyor belt.

[0022] Optionally, the main body includes a first conveyor belt and a housing. The housing is fastened to the first conveyor belt. The cutter and the guide mechanism are both disposed inside the housing. The housing has a discharge port on its side wall. The discharge port extends from the inside to the outside on the side wall of the first conveyor belt and slopes downward.

[0023] By adopting the above technical solution, the exposed cutting blade can be avoided, thus preventing safety accidents. At the same time, the inclined design of the discharge port increases the angle. When the edge material is discharged from the discharge port, it will rub against the discharge port, making it less likely to break. This facilitates the discharge of the edge material and makes it easier to recycle and reprocess it.

[0024] In summary, this application includes at least one of the following beneficial technical effects:

[0025] 1. When the edge material falls from the equipment, the temporary storage tray is placed on the translation table. The gripper can clamp and fix the temporary storage tray to prevent it from shifting. The translation table can move the temporary storage tray freely in the X and Y axis directions on the plane, so that the edge material can be spread out flat and evenly in the temporary storage tray, effectively preventing the edge material from sticking together, which is convenient for subsequent recycling and secondary processing of the edge material.

[0026] 2. The edge material impacts the guide plate under the drive of the main body. The edge material moves along the guide plate to the guide wheel. The guide wheel rotates and discharges the edge material from the outlet, so that the edge material will not scatter around the equipment and cause difficulties in recycling and cleaning. Attached Figure Description

[0027] Figure 1 This is a schematic diagram of the overall structure of the recycling device;

[0028] Figure 2 yes Figure 1 A schematic diagram of the overall structure, viewed in the middle section;

[0029] Figure 3 yes Figure 2 An enlarged schematic diagram of part A in the middle;

[0030] In the picture,

[0031] 1. Main body; 11. Outer shell; 111. Discharge port; 12. First conveyor belt; 13. Cutter; 14. Baffle; 15. Support rod;

[0032] 2. Guiding mechanism; 21. Guide wheel; 22. Guide plate; 23. Adjustment mechanism;

[0033] 3. Conveying assembly; 31. Second conveyor belt;

[0034] 4. Material storage mechanism, 41. Temporary storage tray, 42. Translation table, 421. Gripper. Detailed Implementation

[0035] The following is in conjunction with the appendix Figures 1-3 This application will be described in further detail below.

[0036] Temporary storage mechanism for edge materials 4, refer to Figure 1 The system includes a temporary storage disk 41 and a translation stage 42. The translation stage 42 consists of a platform and two mutually perpendicular and stacked tracks. The translation stage 42 is equipped with grippers 421, which are connected to the translation stage 42 via a computer, allowing the grippers 421 to be loosened or tightened, thus enabling a detachable connection between the temporary storage disk 41 and the translation stage 42. By adjusting the grippers 421 to a loose state, the temporary storage disk 41 is placed between the grippers 421. Then, the grippers 421 are adjusted to a clamping state, fixing the temporary storage disk 41 onto the translation stage 42. The computer controls the translation stage 42 to allow the temporary storage disk 41 to move freely along the X and Y axes of the plane. When the edge material falls from the equipment, the translation table 42 controls the temporary storage tray 41 to move freely in the X and Y directions on the plane. The edge material will start from the starting end of one corner of the temporary storage tray 41 and spread evenly and flatly in the temporary storage tray 41 along an S-shape. It can also be spread in a spiral shape from the inside to the outside or from the outside to the inside in a U-shape. There is space between the edge materials, so the edge materials will not be stacked on top of each other, which effectively prevents the edge materials from sticking together and makes it easier to recycle and reprocess the edge materials later.

[0037] A device for recycling edge material, as described in the following example Figure 2 The device includes a main body 1, a guiding mechanism 2, a conveying assembly 3, and a dough scrap storage mechanism 4. The main body 1 contains a cutter 13, which is rotatably connected to the main body 1. A discharge port 111 is located at the edge of the main body 1, with the cutter 13 and the guiding mechanism 2 also located at the discharge port 111. The dough scrap storage mechanism 4 is located below the main body 1 and to one side of the discharge port 111. The conveying assembly 3 is located below the main body 1. The dough scrap storage mechanism 4 works in conjunction with a dough scrap recycling device. The cutter 13 cuts the dough, and the guiding mechanism 2 guides the cut dough scraps from the discharge port 111, which fall onto the conveying assembly 3 for recycling. If the conveying assembly 3 stops abruptly, the dough scraps enter the dough scrap storage mechanism 4, which prevents them from sticking together. The device ultimately completes the temporary storage and recycling of dough scraps.

[0038] Reference Figure 2 and Figure 3The main body 1 includes a housing 11 and a first conveyor belt 12. The housing 11 is fastened to the first conveyor belt 12, and the cutter 13 and the guide mechanism 2 are both located inside the housing 11. Both side walls of the housing 11 have discharge ports 111, which extend from the inside to the outside on the side walls of the first conveyor belt 12 and slope downwards. A support rod 15, cylindrical in shape, is provided at the bottom of the discharge port 111 and is rotatably connected to the edge of the first conveyor belt 12. A baffle 14, U-shaped in shape, is also provided at the discharge port 111 and is fixed thereto. Two cutters 13 are also provided, each corresponding to a discharge port 111. The cutter 13 is a high-speed rotating circular blade that can cut off the harder parts of the fabric edges to produce edge trimmings, which are then guided out of the discharge ports 111 by the guide mechanism 2.

[0039] Reference Figure 2 and Figure 3 The guiding mechanism 2 includes a guide wheel 21, a guide plate 22, and an adjusting mechanism 23. The guiding mechanism 2 also has two sets, each corresponding to a discharge port 111. The guide wheel 21 is located at the discharge port 111 and is rotatably connected to the main body 1. The surface of the guide wheel 21 has a spiral groove structure; the protruding part of the wheel contacts the edge material, while the grooved part does not, creating intermittent contact between the guide wheel 21 and the edge material, which reduces the adhesion between the edge material and the guide wheel 21 surface. The adjusting mechanism 23 consists of a screw and a nut. The nut is fixed to the edge of the first conveyor belt 12, and the screw and nut are threaded together. One end of the guide plate 22 is fixedly connected to the screw, and the other end is located at the discharge port 111. Rotating the screw allows adjustment of the guide plate 22. The cut-off edge material is conveyed by the first conveyor belt 12 and will collide with the guide plate 22. Then the edge material moves along the guide plate 22 to the guide wheel 21. The guide wheel 21 rotates and drives the edge material to be discharged from the discharge port 111. The edge material slides down the discharge port 111 onto the conveying assembly 3.

[0040] The conveying assembly 3 includes a second conveyor belt 31, which is located below the main body 1. The starting end of the second conveyor belt 31 is located between the discharge port 111 and the dough edge storage mechanism 4. The surface of the second conveyor belt 31 is provided with an anti-stick coating, which can be polytetrafluoroethylene (PTFE), possessing strong non-stick properties and chemical stability. Because the dough is relatively moist during production, the dough edge material will also be relatively moist. Moist dough has a certain degree of stickiness, and if it falls onto the second conveyor belt 31, it will stick to the second conveyor belt 31 and be difficult to remove. The anti-stick coating can prevent the dough edge material from sticking to the second conveyor belt 31, thus effectively completing the conveying and recycling of the dough edge material.

[0041] The implementation principle of this application embodiment is as follows:

[0042] After being conveyed by the first conveyor belt 12, the fabric enters the outer casing 11. Inside the casing 11, a cutter 13 removes the harder edges of the fabric, forming edge trimmings. These trimmings continue moving with the first conveyor belt 12, colliding with the guide plate 22 and moving along it to the guide wheel 21. The guide wheel 21 rotates, pulling the trimmings out of the outlet 111. The trimmings fall onto the second conveyor belt 31 below, where they move, completing the trimmings collection. When the second conveyor belt 31 stops due to a malfunction, the trimmings are stored in a temporary storage tray 41. Controlled by a translation table 42, the temporary storage tray 41 ensures the trimmings are evenly distributed, preventing sticking and completing the temporary storage.

[0043] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be covered within the scope of protection of this application.

Claims

1. A temporary storage mechanism for edge material (4), characterized in that, Includes temporary storage (41) and translation stage (42); The temporary storage disk (41) is located on the translation stage (42). The temporary storage disk (41) and the translation stage (42) are detachably connected. The connection between the temporary storage disk (41) and the translation stage (42) allows the temporary storage disk (41) to move freely in the X and Y axis directions on the plane.

2. The edge material temporary storage mechanism (4) according to claim 1, characterized in that, The translation stage (42) is provided with a gripper (421), which is used to fix the temporary storage disk (41).

3. A device for recycling edge material, characterized in that, The device includes a temporary storage mechanism (4) for edge material as described in any one of claims 1-2, a main body (1) and a guiding mechanism (2). The main body (1) is provided with a cutter (13), which is rotatably connected to the main body (1). The edge of the main body (1) is provided with a discharge port (111), the cutter (13) is located at the discharge port (111), the guiding mechanism (2) is located at the discharge port (111), and the temporary storage mechanism (4) for edge material is located below the main body (1) and is also located on one side of the discharge port (111).

4. The edge material recycling device according to claim 3, characterized in that, The guiding mechanism (2) includes a guide wheel (21), a guide plate (22), an adjusting mechanism (23), and a conveying assembly (3); the guide wheel (21) is located at the discharge port (111), the guide wheel (21) is rotatably connected to the main body (1), one end of the guide plate (22) is fixedly connected to the adjusting mechanism (23), and the other end is located at the discharge port (111), the adjusting mechanism (23) is fixedly connected to the main body (1), and the conveying assembly (3) is located below the main body (1).

5. The edge material recycling device according to claim 4, characterized in that, The surface of the guide wheel (21) has a spiral groove structure.

6. The edge material recycling device according to claim 4, characterized in that, The conveying assembly (3) includes a second conveyor belt (31), which is located below the main body (1). The starting end of the second conveyor belt (31) is located between the discharge port (111) and the edge material storage mechanism (4).

7. The edge material recycling device according to claim 6, characterized in that, The surface of the second conveyor belt (31) is provided with an anti-stick coating.

8. The edge material recycling device according to claim 3, characterized in that, The main body (1) includes a first conveyor belt (12) and a shell (11). The shell (11) is fastened to the first conveyor belt (12). The cutter (13) and the guide mechanism (2) are both located inside the shell (11). The side wall of the shell (11) is provided with a discharge port (111). The discharge port (111) extends from the inside to the outside on the side wall of the first conveyor belt (12) and is inclined downward.